DE1193551B - Switch core matrix - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Int. α .:

H03k

German class: 21 al - 37/60

Number: 1193 551

File number: J 21676IX c / 21 al

Filing date: April 25, 1962

Opening day: May 26, 1965

The invention relates to a switching core matrix, in particular for the calling devices of magnetic core matrix memories, in which the output windings of the switching cores with their associated consumers common bus lines switched on in series between two or more switching cores are.

In the case of large magnetic core matrix memories, such as those in program-controlled calculating machines and Other devices for automatic information processing are used, the calling devices often with switch core matrices to simplify them and to save drivers constructed in which each row and column line of the matrix memory is assigned a switching core as a driver is. In general, these switch core matrices become similar to the memory matrices even operated according to the current coincidence principle. Because the hysteresis loop of the available Magnetic materials deviating from the ideal rectangular shape occur as with the memory cores even with the switching cores in the cores that are only half selected, interference pulses occur. During these glitches However, this can easily be compensated for with the memory matrices, this is with switch core matrices not easily possible, since only one switching core works on each consumer and all switching cores must emit pulses of the same polarity.

A switching core matrix has now become known in which the interference pulses that occur thereby be compensated that the output windings of the switching cores with their associated consumers connected in series and these series connections for one row of the switching core matrix in parallel to two Buses are connected so that the output current of a selected switch core after passing through the associated consumer is essentially evenly distributed over the remaining ones Divides series connections of this line and counteracts the interference pulses that have occurred in it. However, this arrangement has the disadvantage that in it only the half-selected line of the Interference pulses occurring in the switching core matrix, but not the interference pulses in the half-selected column be compensated.

The invention relates to a switch core matrix of the type mentioned at the outset, which this Does not have any disadvantage. This is achieved according to the invention in that each row and each column a bus is associated with the switch core matrix and that one end of each series connection of Switch core matrix

Applicant:
ίο

International Business Machines Corporation,

Armonk, N. Y. (V. St. A.)

Representative:

Dipl.-Ing. H. E. Böhmer, patent attorney,

Böblingen (Württ), Sindelfinger Str. 49

Named as inventor:
Norbert George Vogl jun.,
Wappingers Falls, NY (V. St. A.)

Claimed priority:

V. St. v. America April 26, 1961 (105 797)

Output winding and consumer of a switching core to the bus line assigned to its row and the other end is connected to the manifold associated with its column.

This arrangement, just like the known arrangement, has another disadvantage, namely, that the working resistance of the selected switching core by being connected in series with it Series-parallel combination and thus also the rise time of the output current are not insignificant is enlarged. According to a further feature of the invention, this disadvantage is also avoided, and in that the bus lines each have an inductive resistor with a common Point are connected. The inductive resistances are advantageously dimensioned such that the Voltage drop of the output current of a selected switching core at each of the two in its Circuit lying inductive resistances far-

509 577/163

going to the interference voltage at the output winding continues to be a small change in flux in the cores of an only half-selected switching core. 10 d and 10 g and the input current in the winding In the following, the invention is based on two 14x c a similar small flux change in the Kerin the drawings exemplary embodiments shown nenlOö and 10. FIG. The switched core 10 α play described in more detail. 5 is hereinafter referred to as the "fully selected" core and FIG. 1 shows a first embodiment of the cores 10b, 10c, 10d and 10g, in which only the invention with nine magnetic cores 10a to 10 /, which take place small flux changes, are called "half-inch three horizontal lines and inscribed in three vertical cores chosen. The output current I ₀ columns are arranged with three cores each. All (Fig. 5a), which are induced in the selected output winding cores of a horizontal group by an io treatment 16 α, serves to drive a common row input winding 12. * to 12z row of memory cores in the memory matrix, and all cores of a vertical Group by a der in the output windings 166, 16 c, 16 d and common column input winding 14λ: to 14z 16g induced interference pulse T _n (Fig. 5b) does not meet any coupled. In addition, useful function goes through each driver core and can cause information loss in an output winding 16 to 16 / that in 15 of the memory matrix,
a driver winding for a corresponding row. FIG. 2 shows a drawing of FIG. 1 or the column of the core memory ends. This driver represents and clarifies how the interference pulses from windings serve as a load for the initial application of the inventive concept to a harmonic windings of the driver cores and are reduced in figure 1 loose value. As before, it is assumed by inductance-resistor combinations 18a 20 that core 10a represents the fully selected core up to 18 /. The initial windings each is. According to FIG. 2, the winding diagram of the horizontal group of driver cores is a plurality of return paths for the 20χ to 20 z induced in the output winding 16 a selected in its core-side end to a common line and the output windings each output current I ₀ . All these paths run through a vertical group of driver cores at their loading one of the output windings 16 & and 16 c and one end on the load side to a common line of the output windings 16 d and 16 g, specifically in 22χ to 22 z. a direction similar to that of the induced disturbance

The cores 10 a to 10 / are impulses / “is opposite.

a known type of nuclei, each of which can be located in one of two saturation states, depending on the size of the matrix. There is a number of return paths. For example, nen runs. A current of a given polarity and determined a path through the output winding 16 a, the ge-minimum size in a common line 22 x leading through the core, the output winding 16 b, winding induces flux changes in the core, the common line 2Oy, the output winding it in one of its two saturation states 16 h, the common line 22 z, the output switching or exert no effect on him when 35 winding 16 g and the common line 2Ox zuer is already in the relevant saturation state. back to the output winding 16 a. In this path, an input signal of opposite polarity is the direction of the output current I ₀ in the winding induces the reverse flux changes in the hung 166 and 16 g opposite the direction kern. An input signal that is responsible for the switching of the interference pulses induced in it / ". Therefore, if the required minimum size is not reached, a small differential current flowing in these windings induces equally reversible flux changes in the core; at Be I _n minus a part of I ₀ . Another path ending of these signals the core returns to its is that via the output winding 16 a, the common previous saturation state. A flux change induced in a common line 22 x, the output winding 16 c, the core in turn generates a common line 20 z, the output winding 16 /, voltage at the output 45 leading through the core, the common line 22 y, the output winding. When a core is switched over, 16 d and the common line 2Ox back to, the output voltage thus generated causes an output winding 16 a. Since these paths compared to output current I ₀ (FIG. 5 a), which, apart from the other, e.g. B. the lines not shown 18 ..., rise and fall time, has a constant value. which are supplied by the line 22 χ, the short-Fig. 5b shows the relative duration and size of the 50 ren, it can be assumed that they contain an interference pulse / n, which flows in the output winding of one of the greater parts of I ₀ . The application of the kernel, in which only a small change in the flux of Indu-Kirchhoff's rules was adorned at each branch point, is generated. The duration of the fault of the circuit shows that in each of the halbgewählimpulses is approximately equal to the rise time of the output windings th off about half of I ₀ flows transient current. 55 This generally leads to differential currents, which it is assumed that initially each of the cores not only causes the cancellation of the interference currents, 10 a to 10 / is in the one state of saturation and even an overcompensation as a result of the combined excitation of the line inputs. output windings of the half-selected cores to the output winding 12 and the column input winding result. In a switch larger than that in Fig. 1 14, which lead through it, in the other 60 or 2 shown, however, the fraction saturation state can be brought, the Er- of Z _{0 is} much smaller than half, and there is only excitation However, only one of these windings can cause the mutual compensation of a small change in flux in the core. speaking closer to the desired ideal case. B. input currents are brought to the windings.

12x and 14x are placed, the core 10a at 65. In this arrangement flows into the intersection of these two windings from the closed loop of the switch, which switched the first saturation state to the second. output winding 16 a of the fully selected core does not contain the input current in winding 12 χ, however, does not contain any current. Since all cores 10 a to 10 /

have almost the same hysteresis curves and all half-selected cores are excited by the same excitation currents, the voltages arising on the output windings of these half-selected cores are approximately the same. Therefore z. B. the sum of the induced voltages in the closed conductor loop, the output winding 16 b, the common line 22 x, the output winding 16 c, the common line 20 z, the output winding 16 /, the common line 22 y, the output winding 16 e and the common line comprises 2Oy, equal to zero. Any other closed loop that does not contain the output winding 16 a of the selected core contains a net voltage of zero. No current can therefore flow in these loops.

It has been assumed that the cores 10 a to 10 z were initially in one of their saturation states. After completion of the work cycle described above, the switched core, in the example mentioned the core 10a , is reset to its initial state by a pre-magnetization current or some other known means. This return to the initial state would also induce glitches (- / „) in the output windings of the half-selected cores. These glitches are reduced like the glitches I _n induced in the first cycle, only all polarities are reversed.

With the circuit arrangement shown in FIG. 1, the interference pulses can be compensated to a very high degree. However, this advantage is achieved at the expense of a great increase in the load resistance of the selected driver core 10a. A closed conductor loop containing the output winding 16a contains three further loads 18. Since there are several parallel paths for the output current I ₀ , the load seen by the selected driver core is not increased by a factor of four, but is nevertheless noticeably increased. According to FIG. 5 a and 5 b, the interference pulses I _{n have} a relatively short duration compared to the output current / _0. It would therefore be very desirable to cancel the glitches and then create a resistance-free return path for the output current once the steady state has been reached.

This is achieved in the embodiment of the invention shown in FIG. 3. This circuit differs from that in FIG. 1 shown that at the junction of the common Lines 2Ox, 2Oy and 20 z as well as 22x, 22y and 22z with the core / load lines 16 ... / 18 ... one inductive resistor 24 each connected is. The inductive resistances on lines 2Ox to 20 z are at their other end to a first common line 26 and those on lines 22 λ: to 22 z to a second common Line 28 connected. The common lines 26 and 28 are connected to a common Point 30 connected.

The operation of this circuit is based on Fi g. 4, which is a modified form of FIG. 3 is. Again the kernel 10α is assumed to be the fully chosen kernel. In addition to the in connection with F i g. 2, however, a return path for the current I ₀ via the line 22 x, the inductance 24 in series therewith, the common line 26, the line 20x and the inductance 24 in series therewith is provided in parallel. If the inductances 24 are sufficiently dimensioned, a large part of the output current I _{0 flows} through the output windings of the half-selected cores during the switchover, which causes a cancellation of the interference signals in the same way as in the circuit of FIG. However, once the steady state has been reached, the influence of the inductances 24 drops to zero, and the path described above forms an almost resistance-free return path for the output current I ₀ . During a large part of the working cycle, the fully selected core 10 a only has to work on its own load resistance 18 α.

In order to achieve an optimal cancellation of the interference signals, the inductances 24 must be selected so that the voltage drop generated across them by the output current I ₀ is approximately equal to the interference voltages induced in the windings of the half-selected cores. Then the total voltage in each closed loop that does not contain the output winding 16 a of the fully selected core is zero, e.g. B. in the loop that consists of the output winding 16 a, the line 22 z, the inductance 24 in series, the common line 28, the common line 26, the line 20 χ and the inductance 24 in series therewith, because the interference voltage at the winding 16 g and the voltage dropping across the inductances lying in series with the lines 22 z and 2Ox are of the same magnitude and in opposite directions. Such compensating voltages are found in every other closed loop that does not include output winding 16a. In a circuit implemented in practice, however, the waveforms of the voltages at an inductance 24 and at the output winding of a half-selected core will not be completely the same, so that these voltages do not constantly compensate each other despite the same mean value. There will therefore be short, but completely insignificant, current pulses flowing in the loops mentioned.

Claims (3)

Patent claims: 1. Switch core matrix, in particular for the calling devices of magnetic core matrix memories, in which the output windings of the switching cores with their associated consumers common bus lines switched on in series between two or more switching cores are characterized in that each row (12x, 12 y, 12 z) and each column (14x, 14y, 14z) of the switch core matrix (Fig. 1) a collecting line (2Ox, 2Oy, 20z; 22x, 22y, 22z) is assigned and that one end of each series connection of output winding (16 a) and consumers (18 a) of a switching core (10 a) to the bus line assigned to its row (2Ox) and the other end connected to the collecting line (22x) assigned to its column is. 2. Arrangement according to claim 1, characterized in that the collecting lines (2Ox, 20y, 20z; 22 *, 22y, 22z) are each connected to a common point (30) via an inductive resistor (24) (Fig. 2), 3. Arrangement according to claim 2, characterized in that the inductive resistors (24) are dimensioned in such a way that the stress drop in the output current of a selected switching core (10 a) at each of the two in its circuit lying inductive resistors (24) largely the interference voltage on the Output winding (16 c) of an only half-selected switch core (10 c) is the same. 1 sheet of drawings 509 577/163 5.65 © Bundesdruckerei Berlin